Materials & Design (Feb 2024)

The impact of chemical short-range order on the thermophysical properties of medium- and high-entropy alloys

  • Angelo F. Andreoli,
  • Andrea Fantin,
  • Sergey Kasatikov,
  • Vinícius P. Bacurau,
  • Michael Widom,
  • Piter Gargarella,
  • Eric M. Mazzer,
  • Thomas G. Woodcock,
  • Kornelius Nielsch,
  • Francisco G. Coury

Journal volume & issue
Vol. 238
p. 112724

Abstract

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The unusual behavior observed in the coefficient of thermal expansion and specific heat capacity of CrFeNi, CoCrNi, and CoCrFeNi medium/high-entropy alloys is commonly referred to as the K-state effect. It is shown to be independent of the Curie temperature, as demonstrated by temperature-dependent magnetic moment measurements. CoCrFeNi alloy is chosen for detailed characterization; potential reasons for the K-state effect such as texture, recrystallization, and second-phase precipitation are ruled out. An examination of the electronic structure indicates the formation of a pseudo-gap in the Density of States, which suggests a specific chemical interaction between Ni and Cr atoms upon alloying. Hybrid Monte Carlo/Molecular Dynamic (MC/MD) simulations indicate the presence of non-negligible chemical short-range order (CSRO). Local lattice distortions are shown to be negligible, although deviations around Cr and Ni elements from those expected in a fully disordered structure are experimentally observed by X-ray absorption spectroscopy. The determined bonding distances are in good agreement with MC/MD calculations. A mechanism is proposed to explain the anomalies and calorimetric experiments and their results are used to validate the mechanism.

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